WO2001084150A1

WO2001084150A1 - Biochip for the archiving and medical laboratory analysis of biological sample material

Info

Publication number: WO2001084150A1
Application number: PCT/EP2001/002851
Authority: WO
Inventors: Hans-Jürgen STAAB
Original assignee: Bioref Gmbh
Priority date: 2000-04-27
Filing date: 2001-03-14
Publication date: 2001-11-08
Also published as: JP2004517297A; DE10020704B4; DE10020704A1; DE50113911D1; US8592224B2; US20080138823A1; AU3929801A; ATE393913T1; JP4695812B2; JP5185335B2; ES2305060T3; JP2011017707A; EP1277055A1; US20030124583A1; EP1277055B1

Abstract

A biochip for diagnostic use comprises a sample support consisting of a solid matrix, to whose surface the sample material to be analysed, originating from a biological organism, is bonded.

Description

BIOCHIP FOR ARCHIVING AND LABORATORY MEDICAL ANALYSIS OF BIOLOGICAL

SPECIMEN

Biochip for archiving and laboratory medical analysis of biological sample material, process for its production and its use in diagnostic processes.

The invention relates to a biochip suitable for diagnostic purposes, which is coated with the biological sample material to be analyzed and is suitable both for the space-saving archiving of sample material and for its laboratory medical diagnostic analysis. The invention further relates to sample carriers which are suitable for the production of such biochips, and to methods for producing the named sample carriers or biochips. Furthermore, the invention relates to diagnostic methods using the biochips according to the invention, and to the use of the biochips according to the invention or the diagnostic methods mentioned in various medical fields.

Laboratory medical diagnostics form an important basis for medical treatments. Due to the increasing number of available diagnostic marker molecules, the possibilities of laboratory medical diagnostics are constantly being expanded. Because of the scope of the detection reactions to be carried out, the high urgency and for economic reasons, automated analysis methods are preferably used, which can handle a large number of different analyzes in a short time.

The starting material for laboratory medical analysis of a patient's state of health is usually body fluids, such as whole blood, plasma, serum, urine, ascites, amniotic fluid, saliva, liquor, etc., or tissue samples from the various organs. The attending doctor takes that Patients the sample, subject it to a special treatment, if necessary. B. by centrifugation, and then transfers the patient sample into a sample tube in which the sample can be sent or stored until the analysis is carried out.

Depending on the parameter to be analyzed, i. H. of the components to be analyzed (analytes), the sample can either be at room temperature, or it must be refrigerated or stored in a frozen state. With long-term storage, i.e. H. if stored for a period of several weeks, months or years, the patient samples must be frozen at -20 ° C or at a lower temperature to avoid degradation of the analytes. The main reason for the degradation occurring at room temperature is the enzyme activities contained in the liquid sample material.

Typical sample volumes for long-term storage are at least 500 μl. If, after an initial analysis, further analytical determinations are to be carried out at a later point in time or at different later points in time, then several 500 μl samples must be prepared and stored or stored frozen, based on the blood sample originally taken. These samples take up a relatively large amount of space, making storage over a long period of time relatively expensive. For this reason, long-term storage of patient samples is usually not practiced. This means, however, that the possibility of being able to fall back on a sample taken earlier can be dispensed with. In many cases, this is desirable or even necessary if it is important to compare the current state of a patient, based on a specific diagnostic parameter, with an earlier state in the same patient. It may also be useful to consider several previous patient states different points in time to carry out a trend analysis for the relevant parameter. However, such comparisons are not possible if the diagnostic test (s) in question was not or could not be carried out at the earlier point in time (s) in question, and a retention of the original sample (s) had not taken place.

A wide variety of methods are currently used in laboratory medicine to analyze a patient's state of health. These include, above all, the activity determination of enzymes, special staining reactions, immunochemical methods, cytological methods and molecular biological methods. In recent years, immunochemical processes in particular have gained in importance and replaced many conventional processes. Molecular biological methods are also increasingly used in routine diagnostics.

The immunochemical analysis systems currently used are based on antigen-antibody reactions, which usually take place in a volume of approx. 10-500 μl. The patient sample (body fluid etc.), which contains the analyte to be determined, in this case an antigen, is incubated together with an antibody specific for this parameter, which only recognizes and binds this analyte. The product of this antigen-antibody reaction is a complex that contains antibody-bound antigens. The higher the concentration of antigen in a patient sample, the higher the concentration of antigen-antibody complexes formed. In current test systems, these antigen-antibody reactions either take place freely in solution (detection using turbidimetry or nephelometry), or they are carried out on antigen-specific surfaces (eg RIA, ELISA). After Following the antigen-antibody reaction, the antigen-antibody complexes are in solution in the first case, in the second case they are bound to a solid phase, usually a plastic surface. The detection and quantification of antigen-antibody complexes is carried out in turbidimetry or nephelometry by turbidity measurement, in RIA (radio-immunoassay) by radioisotope-labeled antibodies in connection with radiometric detection, in ELISA (enzyme-linked immunosorbent assay) and LIA with enzy-labeled antibodies in connection with the detection of enzyme-catalyzed color reactions. Using these test systems, analyte or antigen concentrations in the range of up to 1 pg / ml can be detected (protein).

The miniaturization and automation of the above-mentioned analysis systems established in laboratory technology is currently being intensively researched. Various miniaturized, solid-phase-bound test systems have been developed over the past few years, which are referred to as "biochips" due to their small size based on computer chips. The size of such a biochip is typically between 0.25 and 9 cm ² . Biochips described in the literature consist of a solid matrix made of glass (SPA Fodor et al .: Light-directed, spatially addressable parallel chemical synthesis; Science 251 (Feb. 1991), pp. 767-773); CA. Rowe et al .: An array immunosensor for simultaneous detection fo clinical analytes; Analytical Chemistry Vol. 71 (Jan. 15, 1999) pp. 433-439; LG Mendoza et al .: High-throughput microarray-based enzyme-linked immunosorbent assay (ELISA); BioTechniques 27 (Oct. 1999), pp. 778-788), nylon or nitrocellulose membrane, silicone (J. Cheng et al .: Chip PCR. Nucleic Acids Research Vol. 24 (1996) pp. 380-385) or silicon. Biomolecules, e.g. B. DNA, peptides or proteins, covalently coupled to these matrices. On egg- In an area of 3.6 cm ² , up to 10,000 different biomolecules can be applied, which requires micrometer-precise addressing of the biomolecules on special, separate areas of the matrix. This can be done, for example, by a photolithographically controlled synthesis of the biomolecules (SPA Fodor et al .: Light-directed, spatially addressable parallel chemical synthesis; Science 251 (Feb. 1991), pp. 767-773) or by spotting on the biomolecules using fine mechanical , microprocessor-controlled programmable pipetting robots can be achieved (LG Mendoza et al .: High-throughput microarray-based enzyme-linked immunosorbent assay (ELISA); BioTechniques 27 (Oct. 1999), pp. 778-788; M. Eggers et al .: A microchip for quantitative detection of molecules utilizing luminiscent and radioisotope reporter groups; BioTechniques 17 (1994) pp. 516-523).

Using the solid phase-bound biomolecules, the analytes to be analyzed contained in patient samples can then be bound and detected and quantified using suitable detection systems. As detection systems with high sensitivity z. B. charge-coupled-device (CCD) cameras (LG Mendoza et al., M. Eggers et al .; aa 0.), phototransistors (T. Vo-Dinh et al.: DNA biochip using a phototransistor integrated circuit; Analytical Chemistry 71 (1999) pp. 358-363) and fluorescence detectors (SPA Fodor et al .; loc. Cit.).

The biochips described above are currently only used for research purposes, e.g. B. for DNA sequencing, gene expression analysis, gene mutation analysis and protein binding studies, for. B. Antibody binding studies.

In gene expression analysis (M. Schena et al .: Quantitative monitoring of gene expression patterns with a co ple- mentary DNA icroarray; Science 270 (20 Oct 1995) pp. 467-470), DNA sequences that are complementary to certain genes are spotted onto the matrix of a chip blank with the aid of a pipetting robot, each individual spot representing a specific gene. Then mRNA is isolated from the tissue sample to be examined, marked with a fluorescent dye and applied to the entire biochip. The binding of labeled mRNA molecules can then be detected at specific locations on the biochip. After analysis, the biochip is discarded because it is contaminated with the mRNA sample. Similarly, biochips can be used for DNA sequence analysis and gene mutation analysis.

For the immunochemical analysis of sample material, Mendoza et al. (op. cit.) a prototype of a miniaturized test system has been described. The authors used a special glass slide with 96 wells, each well being printed with a dot pattern consisting of 144 different antigens using a pipetting robot and a capillary printing process. After incubation with an antibody-containing solution, those points at which antigen-antibody complexes were formed can be detected using a CCD camera.

The biochips known from the prior art are therefore restricted to those embodiments in which specific, selected or specially synthesized molecules are applied and bound on a solid matrix in a defined, miniaturized arrangement. These molecules are used in a heterogeneous mixture, e.g. B. the patient sample to detect the presence of certain analytes. This means that these biochips are test-specific, ie they only enable those reactions that are determined by the detection molecules on the chip.

This procedure is associated with various disadvantages with regard to laboratory diagnostic use. Although this makes it possible to carry out a large number of different determinations at the same time, it is usually only a limited number of parameters for a specific question, i. H. of analytes, relevant. This means that the majority of the detection molecules on such a chip remain unused or are of no interest. It should also be borne in mind that such a biochip is usually unusable for further analyzes after incubation with the patient sample. For these reasons, the use of biochips of the type described is not very suitable for routine detection methods in laboratory medicine and is not cost-effective to use.

Furthermore, in the previously known biochips, patient sample material is required again for each further analysis to be carried out. This has the consequence that the patient may have to appear several times for blood sampling, which is associated with a certain effort both for the doctor and for the patient. If a certain examination with a sample material already obtained is to be repeated at a later point in time, the sample material must be temporarily stored in a liquid or frozen state, with the disadvantages described at the beginning.

As a result of the ongoing development, new types of detection reactions are continuously made available. In order to make the biochips known from the prior art usable for such newly developed detection reactions, they would have to be constantly updated, which is quite complex and is only possible with a certain time delay.

Often, when a new detection method becomes available, the original sample material of a particular patient is no longer available, so that a temporal change in the laboratory medical parameter of interest can usually not be examined, since the long-term storage of patient sample material is problematic. The biochips known in the prior art cannot contribute to solving this problem.

The object on which the invention is based was therefore to provide a miniaturized analysis system in the form of a biochip for diagnostic purposes, which enables the repeated performance of analytical detection methods, even at larger time intervals, on the same patient sample material. Furthermore, this biochip should enable space-saving storage and archiving of the sample material over a longer period of time.

Furthermore, the object on which the invention is based was to provide a method which enables the automated implementation of detection reactions with a biochip which fulfills the above requirements. The process should be highly flexible, i. H. be easily adaptable to other detection reactions that were not originally intended. In addition, the method should allow repeated testing of the same sample material at intervals.

Surprisingly, it has been found that the problems mentioned are solved by a biochip according to claim 1 and by a diagnostic detection method according to claim 17. The subordinate claims relate to further leadership forms of the invention, which also solve the above object.

According to claim 1, the biochip according to the invention comprises a sample carrier made of a solid matrix, on the surface of which the sample material to be analyzed, originating from a biological organism, is bound. The sample material to be analyzed is therefore bound to a solid phase. In contrast to the biochips known from the prior art, not specifically selected or synthesized molecules are bound to the chip surface in the present case, but the sample material itself, e.g. B. a body fluid, which is a heterogeneous mixture of different biomolecules. The biochip according to the invention consequently represents a patient-specific or patient sample-specific chip, whereas the previously known biochips are test-specific, ie. H. detection-specific biochips.

The sample material can be bound directly to the surface of the matrix of the sample carrier. The matrix or the surface of the sample carrier is preferably pretreated by chemical or physical methods in order to improve the binding ability of the surface for the sample material. Suitable methods for this are known to the person skilled in the art, e.g. B. etching or roughening.

The general structure of the biochips according to the invention can be seen from FIG. 1A, which shows a biochip (a) in section, consisting of a sample carrier (b) and sample material (2) bound thereon. The sample carrier essentially consists of a solid matrix (1).

The sample material can optionally also be bound by means of a layer of linker molecules (linker layer) applied to the surface of the sample carrier. The schematic structure of such a biochip (a) can be seen in FIG. 1B, which shows a section of a sample carrier (b) consisting of a solid matrix (1) and a linker layer (3) thereon, on the surface of which the sample material (2) is bound via the linker layer.

In the biochips according to the invention, the diagnostic detection reaction is carried out in principle in such a way that the molecules suitable for detection are applied to very small areas of the biochip coated with the sample material, as will be described in detail below. In this way it is possible to treat different areas of the surface of the biochip simultaneously or in succession with different diagnostic detection reagents.

Since in the biochips according to the invention the sample material to be analyzed, and not the molecules used for detection, are bound to the surface of the sample carrier forming the matrix of the biochip, the use and the field of application of such a chip are not limited to certain selected diagnostic molecules due to the manufacturing process. Rather, the selection of the useful or required diagnostic detection reagents is made only during the application of the detection procedure. This ensures a high degree of application flexibility.

In the biochips according to the invention, the sample material to be analyzed is bound on the surface of the sample carrier. The sample material is in the dried state and can therefore be stored in a stable manner even at room temperature. Since the biochips according to the invention are miniaturized systems, space-saving and inexpensive storage and archiving patient sample material. In this way, a large number of the patient-specific biochips according to the invention can be stored in a small space and is available for carrying out multiple analytical detection reactions.

The archivability, in conjunction with the possibility of carrying out several detection reactions at different locations on the chip surface independently of one another, makes it possible to examine the presence of a specific diagnostic marker in a specific patient or in a specific sample of a patient at different time intervals. In particular, it is advantageous that such diagnostic examinations are still possible at a later point in time if they were not originally, i. H. were planned at the time of sampling. This is especially true for detection reactions that have only been developed at a later point in time.

Each individual specimen of a biochip according to the invention preferably contains sample material which was obtained from a specific, individual biological organism, e.g. B. Sample material that comes from a particular patient. In addition to humans, other biological organisms from which suitable sample material can be obtained are also animals, plants, fungi and microorganisms.

As the sample material which is bound to the surface of the biochip, body fluids are preferably used, such as e.g. B. whole blood, plasma, serum, urine, ascites, amniotic fluid, saliva, cerebrospinal fluid, lava material from body cavities or bronchoalveolar lavage. Tissue or organ samples, or constituents, cells, fractions, cell disruption material, concentrates or extracts can also be made from the liquids or tissue or organ samples mentioned are used. In certain cases it may be appropriate to pretreat the sample so that the analytes of interest, if present in the sample, are enriched therein. For example, the solid components of the blood sample are separated by centrifugation for a serum analysis; the serum obtained in this way can then be applied as sample material to the surface of the sample carrier and bound.

In a particularly advantageous embodiment, the surface of the sample carrier according to the invention, which is loaded with the sample material, is subdivided into microareas. These are very small areas that are arranged closely next to one another, but are delimited from one another. The surface is usually subdivided into a large number of such microareas, preferably into at least 100 microareas per cm ² . For certain applications, a smaller number of microareas per unit area may also be sufficient, eg. B. 10 to 100

Microareas per cm. The microareas can preferably be configured as depressions or can be delimited from one another by hydrophobic or non-wettable boundary regions. By equipping the sample carrier with hydrophobic or non-wettable boundary areas it is possible to ensure that no binding of sample material takes place in these areas, so that these boundary areas between the individual microareas are free of sample material. The formation of the microareas is exemplified in FIGS. 2 and 3 below.

The subdivision of the chip surface into microareas improves the implementation of the analytical detection reactions, since this measure makes it possible to locate and treat individual sites using a pipetting robot. is lightened. In particular, if the microareas are arranged in the form of a regular grid or grid, individual microareas can be identified and addressed on the basis of their coordinates. This simplifies the selective application of detection reagents to individual locations on the biochip using a pipetting robot. At the same time, the subdivision of the chip surface coated with sample material increases the reliability of detection or prevents the risk of undesired reactions or contamination, since the individual microareas are separated from one another by border areas or are in the form of depressions.

The sample carrier of the biochip according to the invention, on the surface of which the sample material can be bound, essentially consists of a solid matrix. Examples of suitable base materials for the matrix of the sample carrier are silicone, plastics (eg polyvinyl chloride, polyester, polyurethane, polystyrene, polypropylene, polyethylene, polyethylene terephthalate, polyamides, nitrocellulose) or glass, but other solid materials can also be used , Transparent solid materials are preferably used. However, when selecting the matrix material, care must be taken to ensure that it is suitable for the permanent binding of the intended sample material. The sample carrier can also be a laminate of at least two different matrix materials, one of the two layers preferably forming a rigid carrier layer and the other layer serving as a surface for binding the sample material.

As already discussed, it is particularly advantageous if the surface of the sample carrier to which the sample material is to be bound is subdivided into microareas. The external dimensions of the biochip according to the invention are chosen so that the need for miniaturization is met. The area of such a biochip or a sample carrier for the production of such a biochip should be at most 10 cm ² , preferably at most 4 cm ² ', particularly preferably at most 1 cm ² .

The sample carrier or the biochip is preferably designed as a flat structure, particularly preferably with a square or rectangular outline. But other geometric shapes can also be considered, e.g. B. round or circular sample carriers or biochips.

The thickness of the flat sample carrier is preferably less than 3 mm, particularly preferably less than 1 mm. In individual cases, the outer dimensions of the biochip can be selected so that they are compatible with existing pipetting robots or automatic analyzers and enable the use of the biochips according to the invention in such devices.

To produce a biochip according to the invention, the surface of a sample carrier is coated with the biological sample material and this material is bound to the surface of the sample carrier, which can be a covalent or non-covalent bond. In order to improve the ability to bind sample material or biomolecules when using certain matrix materials as sample carriers, it may be appropriate to subject these materials or the surface of the sample carrier to a pretreatment using chemical or physical methods (e.g. etching), which increases the binding capacity. Furthermore, the surface of the sample carrier can be enlarged by chemical or physical pretreatment, which leads to an increase in the binding capacity. Methods suitable for this are known to the person skilled in the art. According to a preferred embodiment of the invention, the surface of the sample carrier can be provided with a linker layer prior to the application of the sample material in order to bind the sample material or the analytes contained therein (eg biomolecules or cells) to the surface of the sample carrier improve, or to effect a selective or preferred binding of certain analytes or groups or classes of analytes. In this way, an enrichment or preselection of certain analytes or groups of analytes can be achieved. In this context, linkers are understood to be those chemical compounds which, on the one hand, are able to form a firm bond with the surface of the sample carrier, ie with its matrix material, and, on the other hand, are able to bind or selectively or preferably bind biological sample material ,

The surface of the sample carrier can preferably be provided with a layer of linker molecules which selectively bind or enrich certain groups of biological macromolecules, preferably proteins, peptides, glycoproteins, sugars, lipids, nucleic acids, or bind or enrich Allow cells or certain cell types or cell populations. Furthermore, it can also be advantageous if different partial areas of the surface of a sample carrier are coated with different types of linker molecules. In this way it is possible to preselect and separate the z. B. Analytes present in a patient sample (e.g. different classes of biological macromolecules).

As linker molecules, for example (LC Shriver Lake; Antibody immobilization using heterobifunc- tional crosslinkers; Biosensors & Bioelectronics Vol. 12 (1997), pp. 1101-1106) use: N-succinimidyl-4-maleimidobutyrate (GMBS; for binding amino groups), 4- (N-maleimidomethyl) -cyclohexane-1-carboxylhydrazide- HCl (M2C2H; for binding sugar residues), or antibodies with known binding specificities for binding a wide variety of macromolecules or cells or cell types.

As already mentioned, it is advantageous if the surface of the sample carrier or the biochip is divided into microareas. In addition to the methods already described, this subdivision can also be achieved by a discontinuously formed linker layer. Microareas are formed from areas containing links and intermediate areas without links, preferably at least 100 microareas per cm ² .

A sample carrier, the surface of which is suitable for binding sample material and is preferably divided into microareas, can be produced in various ways. For the production of flat pieces with the dimensions suitable for biochips, the sheet-like matrix raw material (glass, plastic, etc.), which is usually in large format, is divided in a corresponding manner by means of known mechanical methods, so that sample carriers are obtained. Alternatively, the corresponding matrix raw material can also be liquefied and then poured into appropriate molds, e.g. B. by injection molding to produce sample carriers.

The above-mentioned microareas or the boundary areas in between can be generated, for example, by physical methods, e.g. B. by engraving, punching, embossing or printing, or by chemical methods such as etching or application of hydrophobic layers. It is also possible lent, using a pipetting robot, to apply linker layers in the form of microareas to the surface of sample carriers. Various known printing methods can also be adapted to enable the microareas according to the invention to be generated. Finally, the methods mentioned can also be used in combination. Furthermore, the subdivision into microareas can already be carried out on the flat matrix raw material, which is then divided into individual sample carriers in the manner described.

The biochips according to the invention are particularly suitable for the archiving and repeated diagnostic analysis of sample material from a particular patient in each case ("patient-specific" biochip). In order to facilitate or enable the archiving of such chips and their automatic processing and evaluation in automatic analyzers, it is proposed according to a further embodiment of the invention that the biochip or a corresponding sample carrier is equipped with means for identifying the biochip or storing it of patient-related data or the storage of analysis data. This can preferably be done by means of a machine-readable bar code, a machine-readable magnetic strip, a digital storage element or another computer-readable storage medium. The variant described above is particularly advantageous when large numbers of patient-specific biochips have to be archived or processed.

The presence of an agent for data storage on the biochip enables, for example, the doctor or laboratory doctor who takes the sample and, if applicable, applies the sample material to the sample carrier, e.g. B. patient-related data or data for sampling save on the biochip. Furthermore, it is also possible to save analysis results or their evaluation so that the information about analyzes that have already been carried out can also be stored.

The invention also includes diagnostic detection methods, which comprise process steps for producing a biochip using sample material, as well as process steps for performing diagnostic detection reactions and for evaluating them.

First, body fluids, tissue samples, or the like are obtained from a patient or another organism and, if necessary, subjected to a pretreatment (e.g. centrifugation, concentration, etc.). If necessary, the sample material is suspended or dissolved in a suitable buffer or solvent. To produce a biochip, this sample material, preferably in liquid form, is applied to the surface of a sample carrier according to the invention, e.g. B. using a pipette or by immersion. After a short incubation period of a few minutes, e.g. B. 1 to 10 min, the excess sample material is removed if necessary (z. B. by suction). Drying is then carried out, preferably at slightly elevated temperatures (30-60 ° C.), as a result of which the sample material or the analytes contained therein (e.g. biomolecules) bind to the surface of the sample carrier or, if appropriate, to the linker layer , The aforementioned method steps can be carried out by the doctor who takes the sample material or by medical assistants. The patient-specific or sample-specific biochips obtained in this way can then be stored dry at room temperature and are available for immediate or later analysis. In order to carry out analytical detection reactions on such a biochip coated with sample material, the desired detection reagents are preferably applied to individual locations or to individual microareas of this biochip in the following steps using a pipetting robot. Antibodies, antigens, sequence-specific antibodies, lectins, DNA probes, low molecular weight ligands, hormones, biomolecule-binding dyes or other specifically binding molecules are examples of detection reagents.

The specified locations or microareas of the biochip are incubated for a certain time and at a certain temperature with the selected detection reagents in certain concentrations, the test parameters to be selected in each case depending on the type of detection reagents used and the particular sample material. The person skilled in the art is generally familiar with the selection of suitable test parameters.

At the end of the specified incubation period, the liquid detection reagent is removed by suction using a pipetting robot. Then, in a next step, also using pipetting robots, washing solutions and, if necessary, further detection reagents are applied in sequential order to the sites or microareas of the biochip to be analyzed and then suctioned off again. The wash solutions that can be used and the additional detection reagents to be used, e.g. B. fluorescence-labeled antibodies, as well as the appropriate reaction conditions, are generally known to the skilled worker.

Finally, those sites or microareas in which a positive detection reaction has taken place are identified by a suitable detector. These measurement signals are preferably registered with the aid of CCD cameras, phototransistors or radioactivity, luminescence or fluorescence detectors, the selection of the detection method being based on the type of detection reagents used. The primary measurement data supplied by the detectors can then be subjected to a computer-aided evaluation.

The positive detection reactions basically come about through a specific interaction or bond between the analytes (e.g. certain antigens in the patient sample) and the detection reagent used, e.g. B. Formation of antigen-antibody complexes. These are made detectable by further reaction steps or reagents which are known to the person skilled in the art.

It is particularly advantageous if a larger number of the biochips according to the invention, eg. B. from different patients, simultaneously or in parallel in the manner described, d. H. if the detection reactions and the detection are carried out simultaneously or in parallel on several biochips.

It is also advantageous if the biochip (s) are treated in parallel (simultaneously) or sequentially in succession with different detection reagents with different detection specificities, these detection reagents being applied in each case to locations or microareas of the biochip which have not yet been investigated. In this way, the presence or absence of certain diagnostic marker molecules in several patient-specific biochips can be tested in the shortest possible time. In order to prevent a certain point or microarea of a biochip from being used repeatedly for detection reactions, it can be provided that the position of the "used" points or areas is registered and stored on the storage medium of the biochip. Furthermore, different sites or microareas of the same biochip can also be analyzed with the same detection reagent, possibly in different concentrations. In this way, the reliability of detection can be increased by multiple or parallel measurements.

After the detection reaction and detection have taken place, the biochips can be returned to the archiving and stored. They are available for further detection reactions. This means that the same biochip which is coated with sample material from a specific patient can be subjected to an analysis consisting of detection reaction, detection and evaluation twice or more in succession according to the steps described above, the biochip being in the period between the successive analyzes is kept or archived. In the successive analyzes, different microareas of the biochip are treated with different detection reagents.

The possibility of being able to carry out a large number of diagnostic detection reactions, even at a greater time interval, on a biochip which is coated with sample material of a particular patient, considerably reduces the need for sample material, i. H. Starting from an initially relatively small amount of sample (e.g. 0.5 ml), biochips can be produced that enable a large number of detection reactions over a longer period of time.

The biochips according to the invention with the sample material bound thereon can be stored in the dry state at room temperature for several years, at least over a period of 5 years, and can be stored during this process. can be used several times in the meantime to carry out the described detection reactions. The biochips according to the invention are therefore always advantageous when it is important to store or archive sample material from patients with the possibility of carrying out diagnostic detection reactions. In special cases, when the stability of certain analytes in the sample material appears critical, storage of the biochips at lower temperatures, e.g. B. at 0 ° C to 15 ° C or at even lower temperatures, eg. B. below 0 ° C. Basically, it can be assumed that after long-term or multi-year storage of the biochips in the dry state, extensive inactivation of potentially degrading enzymes, such as nucleases or proteases, has taken place. The storage or archiving of the biochips according to the invention can expediently take place with a lockable box, which has guide rails on its inner side walls, along which the biochips can be inserted into the box and by means of which they are locked in the box. By attaching several such guide rails, more than 100 biochips can be stored in a single box to save space. A larger number of the boxes mentioned can in turn be integrated as a fixed or movable component in a drawer system or cabinet system.

Because of their storability and the possibility of carrying out a large number of independent detection reactions, the biochips according to the invention or the diagnostic detection methods according to the invention are suitable for a large number of useful applications. Some possible applications are described below. The biochips according to the invention can be used in the field of tumor diagnostics, for example to observe the occurrence of certain tumor markers in serum or in tissue samples. These tumor markers are formed by tumors and secreted in the body fluids of the patient, or they are formed by the organism as a result of its reaction to the tumor. On the other hand, these marker molecules are missing in the serum or other body fluids of healthy people, or are only present in small quantities there. As the tumor grows, the serum concentrations of the marker may increase. However, the assessment of "mean" serum concentrations with regard to a diagnosis is problematic, since this finding can indicate an abnormal, but nonetheless acceptable normal value (eg genetically determined) as well as the beginning of tumor growth. The crucial question is therefore whether the serum concentration of such a tumor marker has increased at a certain time. This question can be answered if the serum concentration of this tumor marker is examined at certain time intervals. This is the only way to detect early tumor growth with relative certainty. Fundamentally, such marker proofs must be carried out in time intervals (ie a sequential determination) for each test person so that a trend analysis can be carried out.

The trend analyzes mentioned or sequential determinations of Tu ormarkers using the biochips according to the invention can also be used for monitoring the course of tumors, for. B. for postoperative recurrence control or to control cytostatic therapy.

With the known archiving methods for patient samples, the test series mentioned cannot be carried out or only with great effort. On the other hand, it is biochips according to the invention and the method according to the invention possible to store this sample material in large numbers and in a space-saving manner in the long term, and a large number of diagnostic detection reactions, e.g. B. to determine tumor markers. This enables retrospective trend analyzes that significantly speed up diagnosis. The archivability of the biochips according to the invention also makes it possible to test the presence or absence of newly known tumor markers in older biochips of a particular subject. The invention can thus help to identify the growth of tumors at an early stage and to intervene accordingly.

Furthermore, the biochips according to the invention are suitable for the purposes of clinical research, where the archiving of patient sample material also plays an important role. This is particularly important if - for example when the scientific question changes - follow-up tests on previous patient samples are required. Compared to the methods currently used - freezing of samples (usually at least 0.5 ml) and later thawing - the biochips according to the invention are much more suitable, since they enable a much larger number of detection reactions with a significantly smaller space requirement and easier storage. Because of the large number of detection reactions made possible by a biochip, there is also no need to produce and store several parallel samples from a patient at a certain point in time.

Another area of application of the biochips according to the invention are blood banks or companies or other organizations that process human donor material (eg body fluids, cells, tissue), and for which samples of the donor material and, if applicable, of products made therefrom for diagnostic detection reactions for control purposes should or should. Usually only the analysis results are saved, but not the samples themselves, as this would take up too much space. However, it may also be advantageous in connection with contaminations to subject such samples to a new analysis, if necessary using other detection methods, e.g. B. for legal protection. A re-analysis of such samples can also be advantageous if the proof is to be provided that a raw, intermediate or end product made of human material has met the requirements or legal requirements in its composition. The biochips according to the invention can advantageously be used for the archiving and subsequent analysis of samples from donor blood or other donor material from blood banks, companies and other organizations. The archived biochips make it possible to analyze the suspected donor samples or samples of products based on them in the event of contamination or suspected non-conformity. In retrospect, proof of the conformity of a donor or product sample with the requirements, standards or legal provisions can be provided. This can be of great importance and help, especially in legal disputes. Furthermore, the biochips or sample carriers according to the invention can be used for storing and archiving patient sample material for the purpose of routine diagnosis of patient samples.

The biochips according to the invention can also be used advantageously in epidemiological studies, for example to investigate the spread of infectious diseases. So far, such investigations have often not failed because of this more sample material from the past, since for practical reasons it was not possible to keep the required number of blood samples or the like. In contrast, the biochips described here enable space-saving and inexpensive long-term storage or archiving. This enables a large number of samples to be archived. These samples are available for later epidemiological studies; This means that these studies can take into account a much larger patient population, since they can also access archived samples from the past.

The biochips according to the invention or the methods according to the invention can advantageously be used in connection with various questions in the field of medicine or veterinary medicine. In addition to the application examples already mentioned, applications for purposes of tissue typing or in the field of forensic medicine can also be considered.

1-3, the basic principle and some preferred embodiments of the invention are explained in more detail with reference to FIGS. 1-3. However, the invention is not limited to the illustrated embodiments. The reference symbols are used in the same way in all the figures and each have the same meaning.

1A shows a section through a biochip (a) according to the invention, which consists of a sample carrier (b) and the biological sample material (2) bound on its surface. The sample carrier (b) essentially consists of a solid matrix (1). 1B shows a sectional view of an embodiment of the biochip (a) according to the invention, in which the sample carrier (b) comprises a solid matrix (1) and additionally a linker layer (3) located thereon. The sample material

(2) is bound to the matrix of the sample carrier (1) via the linker layer (3).

2 shows sectional representations of various embodiments of the biochip according to the invention, these embodiments having the above-mentioned microareas (c). 2A to H each show a region of a biochip in which such a microareal is located.

FIG. 2A shows a section through a biochip in the area of a microarea (c), where (b) in turn designates the sample carrier consisting of the solid matrix (1). As can be seen, the biological sample material (2) is bound to the surface of the sample carrier only in the area of the microarea (c). The adjacent areas of the sample carrier surface are free of sample material.

FIG. 2B likewise shows a section through a biochip in the area of a microareal (c), similar to FIG. 2A, but with the sample material (2) over a linker layer

(3) is bound to the matrix (1) of the sample carrier (b). The linker layer is only present in the area of a microarea; the neighboring areas are free of linker molecules.

FIG. 2C also shows a section through a biochip in the area of a microarea (c), similar to FIG. 2A, but the boundary areas (4) surrounding the microareas are provided with hydrophobic properties. tet or are not wettable, so that no sample material (2) can be bound in these border areas.

2 D shows an embodiment in a representation as in FIG. 2 A, in which the measures shown in FIGS. 2 B and 2 C are combined with one another. The sample material (2) is bound to the matrix of the sample carrier via a linker layer (3) located in the area of the microarea (c). In addition, the boundary areas (4) surrounding the microareas have been provided with hydrophobic properties or made non-wettable.

FIG. 2A shows a further embodiment in a representation as in FIG. 2A, a microarea (c) being shown, which is designed in the form of a depression (5) in which the sample material (2) is attached to the matrix (1st ) of the sample carrier (b) is bound.

Fig. 2 F shows a variation of the embodiment shown in Fig. 2 E, wherein a microarea (c) is shown, which is designed in the form of a recess (5), the bottom of which is coated with a linker layer (3), by means of which the Sample material (2) can be bound to the matrix (1) of the sample carrier (b).

FIG. 2 G shows a variant of the embodiment shown in FIG. 2 E, the depression (5) of the microarea (c) being designed in the form of a rounded bowl.

FIG. 2 H shows a variant of the embodiment shown in FIG. 2 F, the depression (5) of the microareal (c) being designed in the form of a rounded bowl.

3 shows an example of some embodiments of the biochips or sample carriers according to the invention in a top view. FIG. 3 A shows the basic shape of a biochip or sample carrier (b) according to the invention, the area provided for coating with sample material being designated by (6). The areas located outside the surface (6), in particular the edge areas, can be made hydrophobic or non-wettable.

FIG. 3 B shows a variation of the sample carrier (b) shown in FIG. 3 A, which is additionally (8) provided with a bar code, magnetic strip or another storage medium.

3 C shows a sample carrier (b) or biochip in a top view, the arrangement of the mentioned microareas (c) being shown as an example. As in FIGS. 3A and B, the edge regions can also be made hydrophobic or non-wettable.

3 D finally shows a variant of the embodiment presented in FIG. 3 C, in which - as in FIG. 3 B - a means for data storage is additionally provided, e.g. B. barcode, magnetic stripe or another storage medium.

Claims

claims

1. Biochip for diagnostic purposes, which comprises a sample carrier made of a solid matrix, on the surface of which the sample material to be analyzed, which originates from a biological organism, is bound.

2. Biochip according to claim 1, characterized in that the biological sample material is bound directly to the surface of the matrix of the sample carrier, wherein preferably the matrix or surface of the sample carrier is pretreated by chemical or physical methods in order to increase the binding capacity of the surface for the sample material improve.

3. Biochip according to claim 1 or 2, characterized in that a single copy of a biochip has in each case sample material from an individual biological organism, preferably an individual patient, bound on its surface.

4. Biochip according to one of claims 1 to 3, characterized in that the biological material bound to the surface is body fluids, preferably whole blood, plasma, serum, urine, ascites, amniotic fluid, saliva, cerebrospinal fluid, lava material from body cavities or bronchoalveolar lavage, or tissue or organ samples, or constituents, cells, fractions, concentrates or extracts from the liquids or tissue or organ samples mentioned.

5. Biochip according to one of the preceding claims, characterized in that the surface of the sample holder is subdivided into microareas, preferably at least 100

Microareas per cm ² , the microareas preferably being configured as depressions or being delimited from one another by hydrophobic or non-wettable border areas.

6. Sample carrier made of a solid matrix, characterized in that it has a surface suitable for binding biological material and is suitable for producing a biochip according to claim 1.

7. Sample carrier according to claim 6, characterized in that the surface suitable for binding biological material is subdivided into microareas.

8. Sample holder according to claim 7, characterized in that the sample holder preferably has at least 100 microareas per cm ² , and that the microareas are designed as depressions or are delimited from one another by hydrophobic or non-wettable boundary areas.

9. Biochip according to one of claims 1 to 5 or sample holder according to one of claims 6-8, characterized in that the area of the biochip or sample holder is at most 10 cm ² , preferably at most 4 cm ² , the sample holder preferably as a flat structure, is particularly preferably designed with a square or rectangular outline, and the thickness of the flat sample carrier is preferably less than 3 mm, particularly preferably less than 1 mm.

10. Biochip or sample holder according to one of the preceding claims, characterized in that the matrix or the surface of the sample holder is pretreated by chemical or physical methods, or that the surface of the sample holder has been enlarged by chemical or physical pretreatment.

11. Biochip or sample holder according to one of the preceding claims, characterized in that the surface of the sample holder is coated with a linker layer through which the sample material is bound in order to improve the binding of the sample material to said surface.

12. Biochip or sample carrier according to claim 11, characterized in that the linker layer is made up of linker molecules which selectively bind or enrich certain groups of biological macromolecules, preferably proteins, peptides, glycoproteins, sugars, lipids or Nucleic acids, or the binding or enrichment of cells or certain cell types or cell populations allow, preferably different sub-areas of the linker layer contain different types of linker molecules.

13. Biochip or sample carrier according to claim 11 or 12, characterized in that the linker layer is discontinuously formed on the surface of the sample carrier, microareas being formed from areas containing links and intermediate link-free zones, preferably at least 100 microareas being present per cm ² ,

14. Biochip or sample carrier according to one of the preceding claims, characterized in that it is equipped with means which enable identification of the biochip or the storage of patient-related data or the storage of analysis data, preferably by means of a machine-readable bar code, a machine-readable magnetic strip , a digital storage element or another machine-readable storage medium.

15. A method for producing a sample carrier according to claim 6, characterized in that sheet-like matrix raw material is broken up mechanically, so that patches with the dimensions suitable for biochips are formed, or that the matrix raw material is liquefied and then by casting process in appropriate Molds is cast, preferably by injection molding.

16. The method according to claim 15, characterized in that the surface of the sample carrier thus obtained is subdivided into microareas, this subdivision

a) by physical treatment of the surface, or b) by chemical treatment of the surface, or c) by printing processes, or d) by applying linker molecules in the area of the microareas using a pipetting robot, or e) by a combination of at least two of the above methods

is achieved.

17. Diagnostic detection method, which comprises the following steps:

a) obtaining biological sample material in the form of body fluids or tissue samples from the organism to be examined; b) production of a biochip by binding the sample material to the surface of a sample carrier by coating with the liquid or suspended sample material, obtained from body fluids or cell or tissue samples, and subsequent drying; c) application of specific diagnostic detection reagents to individual microareas of the biochip using a pipetting robot, and incubation under the conditions suitable for the respective detection reaction; d) application of washing solutions to suppress non-specific reactions, and subsequent suction of these washing solutions; e) if necessary, repeating steps c) and d); f) detection of the measurement signals from positively reacting microareas; g) computer-aided evaluation of the measurement data and storage of the measurement data.

18. The method according to claim 17, characterized in that in step a) the biological sample material is processed before binding to the surface of the sample carrier, preferably by centrifugation, cell disruption or extraction.

19. The method according to claim 17, characterized in that steps c) to g) are carried out on several biochips in parallel or simultaneously.

20. The method according to claim 17, characterized in that individual microareas of a biochip are treated simultaneously or sequentially with different specific diagnostic detection reagents.

21. The method according to claim 17, characterized in that the specific diagnostic detection reagents used in step c) are preferably antibodies, antigens, lectins, DNA probes, biomolecule-binding dyes or other specifically binding molecules.

22. The method according to claim 17, characterized in that the detection of the measurement signals is carried out using CCD cameras, phototransistors or radioactivity, fluorescence or luminance detectors.

23. The method according to claim 17, characterized in that the same biochip, which is coated with sample material of a specific patient, is subjected twice or more in succession to an analysis according to steps c) to f) or c) to g), the biochip in the time between the successive analyzes is kept, and wherein in the successive analyzes different microareas of the biochip are treated with detection reagents.

24. Use of a biochip or a sample carrier according to one of claims 1 to 14 or a method according to steps a) and b) of claim 17 or 18 for diagnostic detection reactions and / or for storing and archiving sample material obtained from patients.

25. Use according to claim 24 for the storage and archiving of patient sample material for the purposes of routine diagnosis of patient samples, clinical research or in epidemiological studies, for quality assurance and control at blood banks, companies or other organizations, or for tumor diagnosis or for forensic purposes ,

26. Use of a method according to claims 17-23 for medical or veterinary purposes, for tumor diagnosis, for tumor marker analysis, in clinical research, for quality assurance at blood banks, companies or other companies, for epidemiological studies, for tissue typing or for forensic purposes ,